ISL54063 Datasheet, PDF(10/15 Page) Intersil Corporation

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ISL54063 Datasheet, PDF (10/15 Pages) Intersil Corporation – 1.8V to +6.5V, Sub-ohm, Dual SPST

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ISL54063, ISL54064

This method is not acceptable for the signal path inputs.

Adding a series resistor to the switch input defeats the

purpose of using a low rON switch. Alternatively, connecting

external Schottky diodes from the V+ rail to the signal pins

will shunt the fault current through the Schottky diode

instead of through the internal ESD diodes, thereby

protecting the switch. These Schottky diodes must be sized

to handle the expected fault current..

V+

+RING

VCOMx

CLAMP

VNOx

VNCx

1kÎ©

LOGIC

INPUTS

GND

-RING

FIGURE 8. OVERVOLTAGE PROTECTION

Power-Supply Considerations

The ISL54063 and ISL54064 construction is typical of most

single supply CMOS analog switches which have two supply

pins: V+ and GND. V+ and GND provide the CMOS switch

bias and sets their analog voltage limits. Unlike switches with

a 5.5V maximum supply voltage, the ISL54063 and

ISL54064 have a 6.5V maximum supply voltage providing

plenty of head room for the 10% tolerance of 5.5V supplies

due to overshoot and noise spikes.

The minimum recommended supply voltage is 1.8V. It is

important to note that the input signal range, switching times,

and ON-resistance degrade at lower supply voltages. Refer

to the âElectrical Specificationsâ tables, beginning on page 4,

and âTypical Performance Curvesâ, beginning on page 11,

for details.

V+ and GND also power the internal logic and level shifters.

The level shifters convert the input logic levels to V+ and

GND signals levels to drive the analog switch gate terminals.

A high frequency decoupling capacitor placed as close to the

V+ and GND pin as possible is recommended for proper

operation of the switch. A value of 0.1ÂµF is highly

recommended.

Negative Signal Capability

The ISL54063 and ISL54064 contains circuitry that allows

the analog input signal to swing below ground. The device

has an analog signal range of 6.5V below V+ up to the V+

rail (see Figure 14) while maintaining low rON performance.

For example, if V+ = 5V, then the analog input signal range is

from -1.5V to +5V. If V+ = 2.7V then the range is from -3.8V

to +2.7V.

Logic-Level Thresholds

This switch family is 1.8V CMOS compatible (0.45V VOLMAX

and 1.35V VOHMIN) over a supply range of 1.8V to 3.3V

(see Figure 16). At 3.3V the VIL level is 0.5V maximum. This

is still below the 1.8V CMOS guaranteed low output

maximum level of 0.45V, but noise margin is reduced. At

3.3V the VIH level is 1.4V minimum. While this is above the

1.8V CMOS guaranteed high output minimum of 1.35V

under most operating conditions the switch will recognize

this as a valid logic high.

The digital input stages draw supply current whenever the

digital input voltage is not at one of the supply rails. Driving

the digital input signals from GND to V+ with a fast transition

time minimizes power dissipation. The ISL54063 and

ISL54064 have been designed to minimize the supply

current whenever the digital input voltage is not driven to the

supply rails (0V to V+). For example driving the device with

2.85V logic high while operating with a 4.2V supply the

device draws only 1ÂµA of current.

High-Frequency Performance

switch -3dB bandwidth of 60MHz (see Figure 19). The

frequency response is very consistent over a wide V+ range,

and for varying analog signal levels.

An OFF switch acts like a capacitor across the open

terminals and AC couples higher frequencies, resulting in

signal feed-through from a switchâs input to its output.

Off-Isolation is the resistance to this feed-through. Crosstalk

indicates the amount of feed-through from one switch

channel to another switch channel. Figure 20 details the high

Off-Isolation and Crosstalk rejection provided by this part. At

decreasing approximately 20dB per decade as frequency

systems, decreasing approximately 20dB per decade as

frequency increases.

Leakage Considerations

Reverse ESD protection diodes are internally connected

between each analog-signal pin, V+ and GND. One of these

diodes conducts if any analog signal exceeds the

recommended analog signal range.

Virtually all the analog switch leakage current comes from

the ESD diodes and reversed biased junctions in the switch

cell. Although the ESD diodes on a given signal pin are

identical and therefore fairly well balanced, they are reverse

biased differently. Each is biased to either the +Ring or -Ring

and the analog input signal. This means their leakages will

vary as the signal varies. The difference in the two diode

leakages to the +Ring or -Ring and the reverse biased

junctions at the internal switch cell constitutes the

analog-signal-path leakage current.

FN6582.0

February 25, 2009

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